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Intravascular Ultrasonic Probe Imaging
During Core Biopsy Procedures
University of Wisconsin-Madison College of Engineering
BME 201 May 4, 2004
Team Members:
Megan Buroker (BSAC) Kevin Johnson (Communicator)
Noelle Simatic (BWIG) Joseph Zechlinski (Team Leader)
Client: Fredrick Kelcz, Ph.D, M.D.
University of Wisconsin Dept of Radiology
Advisor:
Prof. Justin Williams, Ph.D. University of Wisconsin
Dept of Biomedical Engineering
1
Abstract MRI and mammography guided core biopsy procedures are currently subject to high specificity due to inaccurate imaging of small tumors around the biopsy needle. The implementation of an intravascular ultrasonic probe to image the area around the opening of the needle was explored. Ultrasonic imaging has been proven to differentiate abnormal tissue types by the differences in echogenic calcification concentrations. To allow for the use of the IVUS probe within the core biopsy needle a plastic insert was developed to correctly position the needle and reduce needle reflection. Phantoms were performed on orange slices, ultrasonic gel, and turkey using ground cuttle bone to simulate calcifications. With orange slices, the echogenic background prevented differentiation; however, the orange slice was considered a poor model of breast tissue. In ultrasonic gel it was easy to differentiate between surrounding gel and simulated calcifications. Imaging within the turkey breast, the most representative phantom, showed promising ability to differentiate tissue types, but required the use of the insert. Imaging within the needle without the insert had prohibitively high amounts of reflection artifact. Currently the IVUS probe system is not MRI compatible due to the magnetic components, but simple modifications could be made to achieve Zone III compatibility. To bring this system to market, further work is planned to explore probe redesign, imaging of actual excised tissue, and imaging dependence on probe frequency.
2
§1. Problem Statement
During stereotactic biopsy procedures, needle placement is difficult to verify. In cases of
small tumors or calcifications, the needle itself can actually prevent imaging of the suspicious
area. Therefore, many stereotactic procedures lead to false negatives. The goal of this project is
to improve biopsy yields via local imaging around the needle with an intravascular ultrasonic
probe (IVUS).
§2. Background Info
To evaluate the diagnostic power of an IVUS based imaging system both breast cancer
and the core biopsy procedure were evaluated.
§2.1 Breast Cancer
Core biopsy procedures are used to diagnose breast cancer, a disease in which early
detection is crucial for successful treatment [8]. Annual mammograms detect 80-90% of breast
cancers, including small non-palpable cancerous lesions, which cannot be found by self-exams.
Nevertheless, a positive mammogram is only a sign of breast cancer and further testing using
ultrasound and biopsies is often required [7].
Calcifications are small build-ups of calcium and minerals in the breast tissue, and are
indicative of in situ breast cancers. Their frequency increases with age, but in general most are
benign. Further testing is conducted if they constitute a certain size, shape, and distribution [10].
Fortunately, they are particularly visible using X-ray, MRI, or ultrasound.
§2.2 Core Biopsy Procedures
There are many procedures available for excising tissue including fine needle aspiration,
stereotactic biopsy, excisional biopsy, and core biopsy. Core biopsy is a popular option and is
3
very accurate in diagnosing most tumors and calcifications. Small sections of suspicious breast
tissue are removed with a specialized 11-14 gauge needle, which is hollow with a short cutting
edge near its end (Figure 1). For palpable tumors, the needle is simply hand guided; non-
palpable tumors often require image guidance using ultrasound or MRI [4].
MRI has extremely high spatial resolution, and as such, it is an ideal method to provide
accurate imaging feedback during needle insertion. After suspicious tissue is observed in a
mammogram, the patient returns for a second appointment during which the biopsy actually
occurs. An MR image is taken while the breast is immobilized under light compression. A
small incision is made under local anesthesia, and a small plastic clip with a trailing wire is
inserted at the abnormal site. A second MR image then verifies correct placement of the clip,
Figure 1. A Sonos Surgerical vacuum assisted 8 gauge MRI compatibly core biopsy needle. The tubes lead to a pneumatic pump unit which provides cutting power for
cutting and sets up a vacuum.
4
after which the core needle is guided by the protruding wire to the biopsy site. A grid system is
placed beside the breast and used to guide the needle to a preset depth, also aligning it according
to the second MR image. Three to six tissue samples are taken, with the entire procedure lasting
15 minutes [3].
The benefit of core biopsy is that it allows histological analysis by the pathologist.
Comparison between abnormal and normal tissues is then possible, as samples are often large
enough to contain both species. However, only samples of the suspicious area are removed, so
the possibility remains for cancerous sections to be missed. Furthermore, very small tumors and
calcifications may be covered up by the core needle itself. The radiologist is therefore unable to
distinguish whether the tip of the needle is above, below, or exactly at the correct biopsy site.
Should a negative diagnosis be returned, one cannot be sure if the lump is truly benign, or
whether normal tissue was removed instead.
§3. Literature Search
While the idea of placing an intravascular ultrasonic probe within a core biopsy needle
for the purpose of aiding in the precision of its positioning is a novel one, there have been a
number of U.S. patents issued related to the topic.
One method outlined in U.S. patent number 6,669,643 describes the use of catheters in
combination with biopsy devices in order to provide “accuracy, economy, and efficiency in
internal examination, diagnosis, biopsy and surgical removal of lesions” [5]. The device was
designed primarily for use in female vaginal and uterine chambers, and consists of a “tubular
catheter and any of a wide variety of biopsy devices adapted for disposition on or within the
catheter” [5]. A main structural difference in our proposed design is that the imaging probe
would be placed inside the core biopsy needle, whereas in the aforementioned patent an imaging
5
probe is used simultaneously but externally. Given the anatomical differences between breast
tissue and the vaginal chamber, the patented method is not appropriate for our application.
U.S. patent number 6,421,454 describes a method for imaging breast calcifications by
“correlating an ultrasonographic data set with a radiographic image.” However, this method
refers specifically to identifying the position of the calcification before biopsy, and does not
insure placement of the biopsy needle once inside the breast tissue [1].
§4. Design Constraints
The device must adhere to FDA medical device standards, especially the ability to be
sterilized and the requirements for accuracy. The device will be used in conjunction with either
current ultrasound systems or MRI systems. As such, the device should be compatible with
either of the systems. The numerous restrictions for MRI systems must be accounted for in the
design process. Performance-wise, the system must have a spatial resolution of 0.5-1.0 mm in
order to image small calcifications. Also, the device should be able to image the area 1.0-2.0 cm
from the opening of a 9 to 11 gauge core biopsy needle. The workings of the device should not
affect the biopsy procedure, and its use should not significantly increase the procedure time. An
extended list of design constraints is available in Appendix A.
§5. Final Design
Before deciding on an IVUS system, various methods of improving biopsy yield were
investigated, including an optical fluorescence system, an integrated IVUS system, and a catheter
based system. After an extensive analysis of each of design, a catheter-based IVUS system was
determined to be the most effective solution.
6
§5.1 Intravascular Probes
Ultrasound is a well-founded means of imaging, and is commonly used in almost all
hospitals as a safe and effective technique. Typical ultrasonic imaging units consist of two main
elements, a pizo-electric based transducer and an electronic control system. The transducers
convert ultrasonic waves into electrical signals and vice versa. Waveform generation and
perception is done by an electronic control system. This system usually applies a set ultrasonic
sequencing pattern specific to the transducer setup. In conventional imaging, waveforms are
emitted from the transducer and the reflections are read by the same transducer at a frequency
and intensity governed by the echogenisity of the material. In biological imaging, different
tissues have different acoustic impedances, and hence have different reflection frequency
responses. In 2-D and 3-D systems, arrays of transducers are aligned such that a reflection from
a single point is received at multiple transducers. The received signals are out of phase. An
image can be formed through a triangulation method using the known distances between the
transducers. It is highly dependent on sequencing parameters, which ultimately determine the
depth of imaging [6].
Ultrasonic imaging has been modified to allow imaging of veins and arteries in an
invasive technique utilizing an intravascular ultrasonic (IVUS) probe (Figure 2). This probe
consists of a pizo-electric ultrasonic transducer within a catheter that can be inserted into veins
and arteries. A typical transducer used for this procedure is 100-130 cm long and 8-14 F in
diameter. They are generally single-use probes, and currently cost approximately $1000 each.
Two fundamentally different IVUS probes exist: rotational and multi-transducer. The first uses
a motor that spins a single rotating transducer at 1800 rpm, providing a cross sectional image at
roughly 30 frames/sec. The second contains a radial array of transducers which sweep the
7
position of the acoustic beam in radial patterns. A precisely timed transmission/receiving
sequence for the radial array effectively mimics rotational motion. Both methods have a fixed
focal radius, which allows for an imaging depth of 1-2 cm around the probe. Both systems also
use high frequency ultrasound (20-40 MHz) as compared to normal ultrasound (3-5 MHz), thus
achieving higher temporal resolution at a cost of reducing imaging depth. 2-D image
reconstruction is real time; however, spatial resolution is poor. 3-D imaging has been achieved
using similar probes by stacking cross sections with the positions and orientations determined by
a catheter tracking system. Unfortunately these systems are subject to streak artifact. [11]
§5.2 Catheter Based IVUS Probe
An insertable IVUS probe is temporarily placed within an 11 gauge core biopsy needle
just before biopsy. With this method, the rotational probe or multi-transducer array can be used.
Figure 2. 40 MHz Discovery IVUS probe used for testing, on loan from Medical Physics, UW-Madison.
8
While the rotational probes have higher spatial resolution and are generally better for
intravascular imaging, the rotation of the probe may increase the noise created by reflection
within the needle. Both probes are capable of 360 degree viewing; however, because the
transducer is located inside the bore of the needle, its effective viewing angle is limited by the
size of the cutaway portion. With a multi-transducer IVUS probe, it may be possible to turn off
transmission of the transducers that are viewing the highly echogenic walls of the needle.
Therefore, the multi-transducer array may be better suited for this specific purpose, but further
testing is needed to explore its actual imaging properties.
The basic biopsy procedure will be modified when using the catheter based IVUS probe
(Figure 3). The main addition to the procedure is after the third MR image. The IVUS probe
provides fine tuning of the needle placement. Accurate placement of needle is determined by the
imaging presence of calcifications.
Figure 3. A flow chart modeling the revised biopsy procedure.
9
§5.3 Imaging Guide
Due to the extremely high echogenic interface of the needle-to-tissue interface and poor
probe positioning, an insertable plastic imaging guide was created (Figure 4). Ultrasonic
reflection is mostly due to impedance mismatches between materials. The IVUS probe currently
sits inside a plastic based catheter, so the impedance difference between plastic insert and the
plastic catheter should be reduced. Furthermore, by placing the probe in contact with the plastic,
the reflection from the interface can be removed by adjusting the gain. Zeroing the gain from 0-
0.2 mm removes the artifact from the insert but does not significantly reduce the imaging space.
Adjustment of the position of the IVUS probe is required to provide accurate
characterization of the tissue around the needle in 3-D. If the IVUS probe alone is fed down the
needle, its placement is unknown, and may be placed against the back wall of the needle
preventing any imaging of the surrounding tissue. The plastic insert is designed to push the
probe close to the tissue to maximize the imaging of surrounding tissue rather than the area
within the needle (Figure 5). The plastic insert also allows for easier manipulation of the probe’s
position along the longitudinal axis of the needle. The user can easily grip the end of the insert
to adjust position of the probe. The probe is attached to the insert with silicon providing some
viscoelastic damping, filtering out high frequency vibrations that lead to motion artifact. A
groove was etched into the cyclindrical piece to allow a secure fit for the probe catheter. The
effects of inserting the plastic piece into the core biopsy needle during image acquisition are
summarized in Results.
10
Figure 4. A graphical drawing of the IVUS probe with the plastic insert
The plastic insert was constructed from a 3.2 mm soft plastic rod found at a local hobby
store. It was machined using a manual mill and a rod guide created from plexi-glass. This
construction required gluing of the rod to the rod guide with a hot glue gun. Full scale
implementation should be done using injection molded parts.
Figure 5. A 9 gauge core biopsy needle with the plastic insert
11
§5.4 MRI Compatibility
In order for a device to operate in the MR environment, it must be MR safe, operate in
the MR environment, and not effect the MR acquisition. The proposed design is a Zone III
device, meaning that is must be MR compatible in the imaging area, but not during MR
acquisition. The primary concern in Zone III is the magnetism of the materials used to construct
the device. No ferrous materials can be used; however, there are comparable metals and
ceramics with low magnetic susceptibility that can be substituted. Also, the wiring of any
produced device should be void of current loops [2].
While the probe in question was not MRI compatible due to the use of ferrous materials
in the catheter and the motor; compatibility could be easily achieved, given the manufacturing
resources. The conventional electric motor that is currently used to rotate the probe is the
primary problem. In order to repair this problem an air driven motor is suggested. Compressed
air is required to perform the biopsy procedure; hence, it is an ideal power source for a non-
magnetic motor. Currently no motors satisfying the specifications of the device have been
developed; however, many similar motors exist. Ideally, the motor will rotate at 1800 rpm, but
as the reconstruction of images is dependent on the rotation, adjustments could be made to allow
variable rotation. A pneumatic system was not constructed due to a lack of time and limited
knowledge on ultrasound reconstruction. However, an outline for such a device was developed
(Figure 6).
12
§6. Methods and Materials
Tests were conducted under the direction Dr. Jim Zebzeski from the Department of
Medical Physics located in the Medical Sciences building. All testing was done using 40 MHz
Discovery probes attached to an electric control and image reconstruction system. Testing
protocol was developed according to the regulations regarding the use of the IVUS system. In
order to prevent motor burnout, the probe was turned on just long enough to obtain a steady
image, and then turned off until the next image. The probe system was always flushed with
water to ensure that the ultrasonic sound waves would pass through the catheter to image the
surrounding area. The gain on the ultrasound machine was checked so that the signals furthest
Figure 6. An outline for a pneumatically driven IVUS probe system.
13
away from the probe were being amplified more than the objects closest to the probe. This
eliminates much of the noise created by the needle. All testing was recorded continuously on
VHS tape and then digitally captured.
In nearly all cases, the probe was first inserted into an untreated phantom and images
were obtained. Calcifications were then mimicked using “8 in 1: Sun Ripened Fruit Mineral
Treat,” which contained 22.5 to 27% calcium by weight. Small pieces, approximately 3 to 4 mm
in diameter, were manually inserted in the phantom with the probe placed nearby to obtain an
image.
§6.1 Phantom #1 Ultrasonic Gel with Calcifications
To evaluate the raw imaging power of the IVUS system, an imaging test was first
performed using a hollow plastic tube filled with ultrasonic gel. The ultrasonic gel allowed for
imaging of a homogeneous system and allowed the sole imaging of individual calcifications
without background interference. In triplicate, images were taken of the probe in a pure
ultrasonic gel and then compared to images taken from a solution with intermixed calcifications
0.5-2.0 mm in diameter.
§6.2 Phantom #2 Orange Slices and Pulp
To evaluate the effectiveness of IVUS detection of calcification in a medium with
significant interference an imaging test was done using an orange. A fresh navel orange was
ground into a pulp and put into a hollow plastic tube. Images were taken of the baseline phantom
and a phantom with calcification interlaced in triplicate. Images were also taken of individual
slices from the orange with and without simulated calcifications.
14
§6.3 Phantom #3 Water with Suros Needle w/wo insert
To evaluate the effectiveness of the IVUS probe within a core biopsy needle, images
were taken of water with the probe inside a needle. The needle used was a 9 gauge MRI
compatible vacuum assisted core biopsy needle manufactured by Suros Surgical [9]. Three trials
were taken for each of the following conditions: probe alone, probe inside needle, and probe
inside the needle with plastic insert.
§6.4 Phantom #4 Turkey
Raw turkey breast is an accurate model of human breast tissue because it has similar
acoustical impedance. Trials were taken in triplicate of both a normal and a calcified turkey
breast under the following conditions: probe alone, probe with needle, and probe inside needle
with plastic insert.
§7. Results
§7.1 Phantom #1 Ultrasonic Gel
Calcifications were easy to identify using ultrasound gel containing simulated
calcifications (Figure 7). No background noise is noted with gel alone, while possible simulated
calcifications appear as bright spots. The surrounding profile located at the edge of the image is
the hollow plastic tube.
15
§7.2 Phantom #2 Orange Slices and Pulp
Images from orange slices were inconclusive. Phantoms containing simulated
calcifications appeared extremely similar to those without (Figure 8). Exact location of
simulated calcifications was difficult, if not impossible, to determine. It is possible that fresh
orange tissue contains enough calcium to cause background noise. It is not known how well
fresh orange simulates breast tissue.
Figure 8. Orange slice with probe alone without simulated calcification (left) and with simulated calcification (X) (right).
Figure 7. Ultrasound gel with probe alone in hollow plastic tube without simulated calcification (left) and with simulated calcification (X) (right). The profile is of the hollow
plastic tube is visible near the edge of each image.
16
§7.3 Phantom #3 Water with Suros Needle w/wo insert
A strong, sharp profile of the biopsy needle was visible in the absence of the plastic
insert; little background noise was noted in either case (Figure 9, 10). Addition of the plastic
insert reduced needle artifact.
Figure 10. Probe in needle with plastic insert in water (right).
Figure 9. Probe alone in water (left). Probe in needle in water (center). Probe in needle with plastic insert in water (right).
17
§7.4 Phantom #4 Turkey
Very little background noise was noted with the probe alone in raw turkey breast, and
simulated calcifications were easy to detect (Figure 11A, 11B). Strong reflection occurred from
the inner walls of the biopsy needle when the probe was inserted (Figure 11C). It was difficult to
distinguish the cutaway portion of the needle opening from the remainder of its profile.
Calcifications were still visible (Figure 11D). Needle artifact was greatly reduced when the
plastic insert was used, and calcifications stood out more against the black background (Figure
11E, 11F). The plastic insert was weakly visible. In some tests the very edges of the needle
opening remained highly visible, but in all cases the remainder of the needle profile was faint.
The location of the needle could be determined by identifying these bright edges in some images.
In general, distinguishing the needle profile from the cutaway portion (where tissue was located)
was much easier in video footage versus a static image. As the probe was fed in and out through
the tissue, the cutaway portion of the image changed greatly as tissue passed by the transducer,
while the portion of the image showing the needle profile remained nearly static.
18
Figure 11. Phantom is raw turkey breast without simulated calcifications (left: A, C, E) and with simulated calcifications (X) (right: B, D, F). Imaging type is probe alone (top: A, B), probe in
needle (middle: C, D), and probe in needle with plastic insert (bottom: E, F).
A B
C D
E F
19
§8. Discussion
The catheter-based IVUS system is a promising one, especially when the plastic insert is
used in conjunction with the probe. In the final phantom, the raw turkey breast, calcifications
were clearly visible against a black background. The turkey breast is an excellent model for
human breast tissue; we believe similar results are possible with a real specimen. The plastic
insert removed most of the needle artifact in the turkey phantom, allowing higher contrast for
viewing calcifications. Better imaging was also possible with the plastic insert as the transducer
was always positioned at the opening of the biopsy needle. Without the insert, the transducer
was positioned closer to the needle wall in some images, limiting the viewing angle.
In tests completed so far, the probe was not glued to the plastic insert as in the final
design. Rather, the two were held together by hand while insertion into the needle. Images
should be obtained with the probe glued to the insert, so as to characterize the viscoelastic effect
the glue may have on the system. Additionally, the phantoms did not test the ability of the IVUS
probe to differentiate breast tumors from normal tissue. Rather, only simulated calcifications
were used. If the probe is not able to correctly identify breast tumors, its application is severely
limited.
§9. Future Work – Potential Problems
To bring this design to market, there are many avenues that could be pursued, each with
distinct pros and cons. One avenue that could be pursued is a complete redesign of the IVUS
system. While this method would require an extensive amount of work, it may be the most
practical long term solution. Currently IVUS probes are manufactured to fit in the smallest of
arteries, and hence are costly ($1000/procedure). In the case of biopsies, the probe may be much
larger, and therefore less costly. This system could also include the redesign of the motor to
20
allow for MRI compatibility. Hospitals should be able to use the same IVUS equipment they
currently have, by simply using a new probe. However, this method may take an extended
period of time to develop.
The quickest way bring the system to market is to perfect the current method and
evaluate it with more complex phantoms. The first phantom that could be tested would be a
mammography coupled phantom. A mammogram may be taken of one of the current phantoms
to determine the size, shape, and distribution of calcifications. This could be done at the medical
physics labs using a Siemens ultrasound machine with an 8 MHz linear probe. Also, phantoms
have not been done with real tissue. Additionally, tumors could be simulated in turkey breast
using olive pieces. Such tests must be performed to validate the system. This method will not be
MRI compatible; however, it could be used with mammogram guided biopsies.
21
§10. References
1. Burke, T.M. and Carrott, D.T. 2002. Optical correlator assisted detection of calcifications for breast biopsy. US Patent, 6,421,454.
2. Chinzei K, Kikinis R, Jolesz F. 1999. MR Compatibility of Mechatronic Devices: Design
Criteria. Proc. MICCAI 99 Lecture Notes in Computer Science. 1679:1020-31. 3. Core Needle Biopsy. Imaginis. Last Updated: January 5, 2001. Date Accessed:
February 8, 2004. URL: http://imaginis.com/breasthealth/biopsy/core.asp. 4. Diagnosis by Biopsy. 2003. The Breast Center at Southern Illinois University School of
Medicine. Date Accessed: February 9, 2004. URL: http://www.siumed.edu/breastcenter/diagnosis.html.
5. Dubinsky, T.J. 2003. Method and apparatus for sonographic examination, biopsy, and
excision. US Patent, 6,669,643. 6. Lees W. 1999. 3 and 4 Dimensional Ultrasound Imaging. Medicamundi. 43(3):23-30 7. Nissen S. 2001. Coronary angiography and intravascular ultrasound. Am J Cardiol.
87(4A):15A-20A 8. Signs & symptoms. (2003) National Breast Cancer Institute. Retrieved February 11, 2004
from http://www.nationalbreastcancer.org/signs_and _symptoms_/index.html 9. Suros Surgical: Product Line. 2004. Suros Surgical. Retrived April 24, 2004 for
http://www.surossurgical.com. 10. Trevino, M. (2003, December 12) Calcifications may be presage invasive breast cancer.
Diagnostic Imaging Online. Retrieved February 11, 2004 from http://www.diagnosticimaging.com/dinews/2003121201.shtml
11. Yock, P., Johnson, E., and David, D. Intravascular ultrasound:Development and clinical potential. American Journal of CardiacImaging 2(185)
22
Appendix A.
Project Design Specification May 5, 2004 Team Members: Kevin Johnson, Noelle Simatic, Joe Zechlinski, Megan Buroker
Problem Statement: The goal of this project is to improve breast biopsy yield by local imaging during MRI and Ultrasound guided stereotatic biopsy procedures. Client Requirements:
• Spatial resolution must be approximately .5-1mm • Depth perception must be approximately 3-5mm • Must be equal to or less than two hundred dollars • Must be able to distinguish small tumors and calcifications from normal tissue • Must be able to operate within core biopsy needle with minimal artifact • Must be MRI compatible (non-magnetic)
Design Requirements:
1. Physical and Operational Characteristics a. Performance Requirements- The device must distinguish between small
tumors/calcifications and normal breast tissue during core biopsy procedures. b. Safety- The device must comply to standards for medical devices established by the FDA .
The device also must not increase the risk of the operation procedure for the patient. c. Accuracy and Reliability- Results must be repeatable. It must improve the accuracy of
current biopsy procedures. It must have a spatial resolution of 1-2 mm, and a depth perception of 3-5 mm.
d. Shelf Life- Typically the type of probe that will be incorporated into our design is only used for one or two applications.
e. Operating Environment-Must operate in sterile operation conditions. For MRI probe, it must be able to operate in a magnetic field of approximately 1.5-3 T.
d. Ergonomics- The modifications must be non-obtrusive to the surgeon while they are performing the biopsy. The wires that connect the probe to the data interpretation equipment must not impair the surgeon’s movements. Display must be clearly visible to user while in MRI suite.
e. Size and Shape- Must fit within the core biopsy needle. The needle has an internal diameter of 3-5mm; 7 and 14 gauge needles.
f. Weight- Must be able to be hand held for the duration of the biopsy procedure. g. Materials- Must be non-magnetic or minimally magnetic in order to be used in the
MRI suite. They must be able to be sterilized and biocompatible for use during the biopsy procedure.
f. Aesthetics – No constraints.
2. Product Characteristics: a. Quantity – Only one device is needed. b. Target Product Cost- The device should cost equal or less than two hundred dollars.
23
3. Miscellaneous: a. Standards and Specifications- The device should comply to the guidelines setup up by
the FDA for medical instruments. Further information is available online at the FDA’s website, but it too extensive to specifically list. The device is classified as a Class II medical instrument, and is subject to performance and safety standards without exemption.
b. Customer- The device must be non-obtrusive to the surgeon while he/she is performing the biopsy. The wires that connect the probe to the data interpretation equipment must not impair the surgeon’s movements. Additionally, the probe must provide a determinate image of the needle placement in relation to the lesion in question.
c. Patient-related concerns- The use of this device should not prolong the overall biopsy procedure in any way, but rather enhance the accuracy of the breast biopsy procedure.
d. Competition- U.S. patent number 6,669,643 describes the use of catheters in combination with biopsy devices, however this is primarily for use in female vaginal and uterine chambers, rather than the breast biopsy procedure. Optical fluorescence is currently being developed as a method in order to guide biopsy needles by Dr. Nimmi Ramanujam, an assistant professor in the Biomedical Engineering Department at UW-Madison. Her device was developed based on the characteristic way in which molecules in cancerous cells respond to the fluorescence from the optical fiber.
24
Appendix B. Ethical Concerns
There are number of things to keep in mind while designing a new medical device or
making modifications to existing technology. The overall cost for a patient undergoing core
breast biopsy procedures has the potential to be lower than the cost for those who may miss an
early diagnosis and undergo an extensive cancer treatment. The goal of this design is to make
the biopsy process even more exact. Consequences that could potentially emerge include rising
procedural costs as well as an extended procedural time. Additionally, doctors will need to
adjust their biopsy practice to include the use of this probe, requiring more time and training.
When assessing the overall impact of the implantation of this new medical device on the
health care system, some potential consequences can result. While it may seem that the use of
this device will lower patients’ health costs in the long run, the procedure may actually lead to an
increase in the cost of health care overall. If the procedure proves lengthier than expected, a
potential consequence for the doctors would be that they would not be able to take as many
patients in one working day. This could lead to an increase in the cost of the procedure to
compensate for any lost profits from seeing fewer patients. Additionally, IVUS single-use
probes can be quite costly, ranging from $1000 to $1500 each. At this current time the actual
cost of the procedure is unknown, and it is therefore difficult to predict whether or not it will
prove financially advantageous when considering the overall costs of treating the patients.
With any new device, training and familiarization with the technology is required. Until
the doctors utilizing this technology are able to properly execute the procedure, a greater
possibility of inaccurate results exists. In the future, if such a device is implemented into the
breast biopsy procedure, an assessment of its benefits will need to be formed in order to
conclusively determine its value.
25
Appendix C. Project Expenses Item Cost Cuttle Bone $5.00 Turkey Breast $8.00 Plastic Insert Material $4.00 Use of IVUS probes $0.00 Machining Help $0.00 Total $17.00
26
Appendix D. Needle Schematic